簡易檢索 / 詳目顯示
| 研究生: |
林文清 Wen-ching Lin |
|---|---|
| 論文名稱: |
微晶纖維素廢料之活性碳熱裂解資源化研究 The hot cracked recycle treatment of activated carbon of microcrystal cellulosic waste material is studied. |
| 指導教授: |
王鯤生
Kuen-sheng Wang |
| 口試委員: | |
| 學位類別: |
碩士 Master |
| 系所名稱: |
工學院 - 環境工程研究所在職專班 Executive Master of Environmental Engineering |
| 畢業學年度: | 95 |
| 語文別: | 中文 |
| 論文頁數: | 143 |
| 中文關鍵詞: | 孔隙結構 、比表面積 、活性碳 、微晶纖維素 、碳化 、活化 |
| 外文關鍵詞: | activation, carbonation, Microcrystal celluloseeic, spectiv surface area, activated carbon, pore structure |
| 相關次數: | 點閱:18 下載:0 |
| 分享至: |
| 查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報 |
本研究利用化學製藥廠之微晶纖維素賦型劑廢料於裂解爐進行碳化產製活性碳,裂解爐採用氮氣(N2)氣氛與固定升溫時間的操作條件。以碳化溫度、碳化時間與活化溫度、活化時間為實驗變數,藉由元素分析、BET比表面積、孔隙尺寸及分布特性,探討裂解爐的操作條件對微晶纖維素廢料進行活性碳資源化的影響,並提出最佳的碳化條件與活化條件;並藉由活性碳對重金屬(Cu,Pb)之吸附實驗,檢視活性碳之吸附能力。
在碳化實驗方面,活性碳產量介於10.1-14.6%之間,產量與碳化溫度及碳化時間均呈負相關性;碳化溫度、時間與比表面積呈正相關性,於溫度900℃與120min之碳化條件下,活性碳的比表面積達到最大,平均孔隙尺寸介於1.83-1.93nm,孔隙直徑分佈集中於3-400nm之間,微孔佔總孔隙體積達93.3%。在活化實驗方面,產量介於10.2-13.3之間,產量與碳化溫度及碳化時間均呈負相關性,活化溫度、時間與比表面積呈正相關性,平均孔隙尺寸介於1.91-1.96nm,孔隙直徑分佈集中於3-400nm之間,微孔佔總孔隙體積達94.5%;在元素分析方面,裂解前後對C與H會產生較大變化,而S與N則變化較小,C含量隨著裂解溫度升高而降低,但變化幅度不大。本研究最佳的活性碳備製條件為碳化溫度900℃、碳化時間為120min,與活化溫度900℃、活化時間120min。本研究同時利用活性碳吸附模式,預測重金屬吸附程度,結果顯示活性碳對於高濃度之Cu、Pb溶液具有良好之吸附效果,反應時間約只要5min即可得到良好之效果。
This research utilizes a little brilliant cellulose composing type pharmaceutical waste material of the chemical pharmaceutical factory to carry on carbonization and produce and make activated carbon in the cracked stove, the cracked stove adopts the nitrogen (N2) The atmosphere, with intensifying the operation condition of time regularly. Turn time into the experiment parameter with carbonization temperature, carbonization time and temperature of activating and livingly, with ultimate analysis, BET than surface area, size of hole and characteristic of distributing, the operation condition of probing into cracked stove is to the influence of carrying on recycle treatment of activated carbon of a little brilliant cellulosic waste material, put forward the best carbonization condition and activate the condition; And to the heavy metal (Cu, Pb) with the activated carbon Absorb it test,look over by activated carbon it last function.
In carbonization experiment, the output lies between 10.1-14.6%, the output and carbonization temperature and carbonization time present and shoulder dependence; Carbonization temperature, time and presenting dependence in the hope of being improved than the surface area are under the carbonization conditions of 900 degrees Centigrade of temperature and 120min, to reach than surface area most heavy activated carbon, average hole size lie between 1.83-1.93nm, hole diameter is it concentrate on 3-400nm to distribute, the capillary accounts for the volume of total hole and is up to 93.3%. In activating the experiment, the output lies between 10.2-13.3, the output and carbonization temperature and carbonization time present and shoulder dependence, activate temperature, time and present dependence in the hope of being improved more than the surface area, average hole size lie between 1.91-1.96nm, hole diameter is it concentrate on 3-400nm to distribute, capillary account for total hole volume up to 94.5%; In ultimate analysis, will produce bigger change to C and H before and after splitting decomposition, but S and N had little change, C and the content is reduced as cracked temperature rises, but it is not high to change the range. So best activated carbon for carbonization of 900 degrees Centigrade in temperature, carbonization time 120min prepared terms, with activating 900 degrees Centigrade of temperature, activating time 120min. This research utilizes activated carbon to absorb the way at the same time, predict the heavy metal absorbs the degree, the result shows the theory way predicts that gets good verification with the experimental analysis one.
〔1〕Tanju,Karanfil,“Role of Granular Activated Carbon Surface hemisty on the Adsorption of Organic Compounds”(1999).
〔2〕Lua,A.C.,and Guo,J.,“Activated carbon prepared from oil palm stone by one-step CO2 activation for gaseous pollutant removal”(2000).
〔3〕Pastor-Villegas,J.,and Duran-Valle,“C.J.,Pore structure of activated carbon prepared by carbon dioxide and steam activation at different temperatures from extracted rockrose”(2002).
〔4〕Tamon,H.,Okazaki,M.,“Influence of acidic surface oxides of activated carbon on gas adsorption characteristics”(1996).
〔5〕Caturla,F.;Molina,S.M and Rodriguez,R.F.,“Preparation of Activated Carbon by Chemical Activation with ZnCL2”(1991).
〔6〕Brunauer,S.,P.H. Emmett and E.Teller,“Adsorption of gases in multimolecular layers”.J.Amer.Chem.(1938).
〔7〕Langmuir,I.,“The adsorption of gases on plane surfaces og glass,mica and platinum”.J.Amer.Chem.Soc 40(1918).
〔8〕Freundlich,H.,“Ueber die Adsorption in Loesungen.Z.physik”.Chem(1907).
〔9〕Boehm,H.P.,“Some Aspects of The Surface Chemistry of Carbon Blacks and Other Carbons”,Carbon,32(1994).
〔10〕Wigmans,T.,“Industrial aspects of production and use of activated carbons”(1989).
〔11〕Biniak,S.,M.Pakula,G.S.Szymanski and Swiatkowski,“Effect of activated carbon surface oxygen-and/or nitrogen-containing groups on adsorption of copper(II)Ions from aqueous solution”.Langmuir 15:6117(1999).
〔12〕Park,S.J.and K.D.kim,“Influence of activation temperature on adsorption characteristics of activated carbon fiber composites”.Carbon 39:1741-1746(2001).
〔13〕Gregg,G.S.and K.S.W.Sing,“Adsorption,Surface Aera and Porosity.2nd edition”.Harcourt Brace Jovanovich,London,England(1982).
〔14〕Rudzinski,W.and D.H.Everett,“Adsorption of gases on heterogeneous surfaces”.Harcourt Brace Jovanovich,London,England(1992).
〔15〕Harkins,W.D.and G.Jura,“Vapor adsorption method for determining the area of solid without assumption of a molecular area”.J.Am.Chem.soc.(66):1366(1944).
〔16〕Lewis,I.C.,“Chemistry of Carbonzation”,Carbon,20,519(1982).
〔17〕Cprapcioglu,M.O.,and Huang,C.P.,“The surface acidity and characterization of some commercial activated carbon”,Carbon,25,pp569(1987).
〔18〕Bansal,R.C.,Donnet,Jean-Baptiste,and Stoeckli,F.,“Active Carbon,Marcel Dekker”,INC.,New York and Basel(1988).
〔19〕Suzuki,M.,“Adsorption Engineering”,Elsevier,Amsterdam,35(1990).
〔20〕Lu,G.Q.,“Evolution of Pore Structure of High-ash Char during Activation”.,Fuel,145,73(1994).
〔21〕Ruthven,D.M.,“Principles of Adsorption Process,John Wiley and Sons”,New York,(1984).
〔22〕Dubinin,M.M.,and Plavnik,G. M.,“Microporous Structures of Carbonaceous Adsorbents”.,Carbon,6,183(1989).
〔23〕Rodriguez-Reinoso, F., “The Role of Carbon Materials in eterogeneous Catalysis” ,Carbon,36,159(1998).
〔24〕Hassler,J.W. “Rurification with Activated Carbon:Industrial Commerical Evironmental”,Chemical Publishing Co.Inc.,New York(1974).
〔25〕R.A.Hutchins,“Economic Factors in Granular Carbon Thermal Regeneration”,Chem.Eng. Prog.,Vol. 69,No.11,pp48-55(1973).
〔26〕Doelker,E.“Comparative compaction properties of various microcrystalline cellulose and generic products.Drug Dev”.Ind Pham,19,2399-2471(1993).
〔27〕Chaudhuri,S.K.,Batabyal,D.,Sahu,A.“Kinetics and Desorption Studies in the aqueous Phase for the Toluene/Activated Carbon System”.Environ.prog(1994).
〔28〕Peel,R.G.“The Roles of slow Adsorption and Biological activity in activated carbon modeling ph”.D.thesis,Mcmaster univ.Hamilton,ontario(1979).
〔29〕Poots,V.J.P.,Mckay,G and Healy,J.J.“The removal of acid dye from effluent using naturally occurring adsorbents”-II.wood.water res,10,1067(1976).
〔30〕Bhattacharya,A.K.and Venkobachar,C.“Removal of cadmium(II)by low cost adsorbents” J.environ.eng,110,110(1984).
〔31〕Hutchinson,T.C.,and Meema,K.M.,“Lead,Mercury,Cadmium,and Arsenic in the Environment”,Scientific Committee on Problems of the Enviroment(SCOPE),PP.69-87(1987).
〔32〕Brunner,C.R.,“Hazardous Air Emission from Incineration”,Chapman and Hall Ltd,New York,pp.38-47(1985).
〔33〕Stoeppler,M.,“Hazardous Metals in the Environment”,Elsevier Science Publishers.Inc.,Netherlands(1992).
〔34〕Tchobanoglous,G.,Theisen,M.,and Vigil,S.,“Integrated Solid Waste Management Enginnering Principles and Management Issues”,McGraw-Hill,Inc.,Singapore(1993).
〔35〕財政部關稅總局網站(http://web.customs.gov.tw)(2006)。
〔36〕劉曾旭,「活性碳製造技術及應用」,產業調查與技術,127期。郭天和等人,中興工程第八十三期(1998)。
〔37〕曾如玲、吳豐智、曾四恭,「龍眼籽製備活性碳吸附水中酚類之研究」,台灣農業化學與食品科學(2003)。
〔38〕曾如玲、吳豐智,「四種產業廢棄物備製活性碳之孔隙結構與吸附行為」,聯合學報,22 期(2003)。
〔39〕曾如玲、吳豐智,「木質廢棄物備製活性碳之研究」,技術學刊(1999)。
〔40〕曾如玲、吳豐智,「木質活性碳備製、吸附特性和孔隙結構」,吸附與離子交換專刊。
〔41〕陳文樟,「中鼎月刊」,321期,(2006)。
〔42〕陳弘彬,「孟宗竹炭與活性碳之研製」,國立屏東科技大學森林系研究所碩士論文,(2003)。
〔43〕周佳慧,「活性碳孔洞結構對不同氣體有機物吸附之影響」,國立成功大學化學工程系研究所碩士論文(2001)。
〔44〕謝建德,「活性碳孔隙結構與備製條件對液相吸附的影響」,私立中原大學化學工程系研究所碩士論文(1998)。
〔45〕徐惠美,「經濟部產業技術資訊服務推廣計畫」(2002)。
〔46〕李建民,「以木屑備製活性碳與其應用之研究」,國立台灣科技大學化學工程研究所碩士論文(2002)。
〔47〕環保署網站,(http://w3.epa.gov.tw)(2006)。
〔48〕王桓娟,蔡士昌,「重金屬廢水處理技術(上)(下)」,台灣環保產業雙月刊第26、27期(2004)。
〔49〕吳萬全,「活性碳」,台灣礦業53(3):37-51(2001)。
〔50〕經濟部工業局污染防治技術服務團,「工業廢水活性碳處理」,工業污染防治技術手冊之七,財團法人中國技術服務社編印(1987)。
〔51〕王明光,王敏昭,「實用儀器分析」,國立編譯館主編(2002)。
〔52〕劉瑞華,「低濃度揮發性有機物在吸附劑中之傳輸與平衡研究」,國立成功大學環境工程研究所碩士論文(1998)。
〔53〕潘泰安,「以農業廢棄物為原料合成微孔吸附劑之資源化研究」,國立高雄第一科技大學環境與安全衛生工程研究所論文(2003)。
〔54〕呂金堂,「以serratia marcescens P-125吸附重金屬之研究」,大同大學生物工程研究所論文(2001)。
〔55〕謝明安,「微晶纖維素之物理性修飾」,台北醫學院藥學研究所論文(1997)。
〔56〕謝堅銘,「以共製法結合賦形劑之微晶纖維素的特性與功能性研究」,台北醫學院藥學研究所論文(1998)。
〔57〕吳振森,「微晶纖維素的製程因子對其材質與機械性能及應用功能性的影響」,台北醫學院藥學研究所論文(2000)。
〔58〕李世龍,「利用農業廢棄物玉米穗軸製造粒狀活性碳之可行性研究」,台灣大學環境工程研究所論文(1996)。
〔59〕樊邦棠,「環境工程化學」,科技圖書股份有限公司,台北(1994)。
〔60〕陸杰人,「環工科學概論」,新學識文教出版中心,台北(1988)。
〔61〕阮國棟,「工業廢水處理技術(I)有害成分去除法」,科技出版社,新竹(1988)。
〔62〕洪崇彬,「木質廢棄物製造之碳化材的基本性質與利用」,國立台灣大學森林學研究所博士論文第1-115頁(2002)。
〔63〕洪禎禎,柳杉粒片含脂率及碳化條件對木陶瓷基本性質與吸附性能之影響,國立台灣大學林學研究所林產組碩士論文第1-58頁(2003)。
